Karl J Kaiyala1, Shehzad Butt, Douglas S Ramsay. 1. Department of Dental Public Health Sciences, University of Washington, Box 357475, Seattle, WA 98195-7475, USA. kkaiyala@u.washington.edu
Abstract
RATIONALE: Nitrous oxide (N(2)O) can initially lower core temperature (T (core)), but hypothermic tolerance develops with chronic administration. Therefore, one or both of T (core)'s controlling determinants, heat production (HP) and heat loss (HL), must adapt across repeated N(2)O administrations. Simultaneous measurements of HP, HL, and T (core) during chronic N(2)O administrations will elucidate this adaptive process and constitute a rigorous model for studying the systems-level dynamics of tolerance in both mature and young animals. This approach is justified by the need to better understand the increased vulnerability to addiction associated with adolescent drug use. OBJECTIVES: The objective of the study was to measure HL and HP across repeated steady-state administrations of 60% N(2)O in young and mature rats. MATERIALS AND METHODS: Synchronous measurements of HP (indirect calorimetry), HL (direct calorimetry), and T (core) (telemetry) were obtained during 60% N(2)O administrations in adolescent (28-45 days, n = 11) and mature rats (>90 days, n = 8). Rats received five 90-min drug exposures (every other day). RESULTS: Compared to mature rats, adolescents initially exhibited greater hypothermia, but acquired tolerance more rapidly and actually developed hyperthermia during the fifth administration. In both groups, N(2)O consistently increased HL, but progressive increases of intrasessional HP over repeated administrations prevented hypothermia and subsequently promoted hyperthermia in adolescent rats. CONCLUSIONS: Adolescent rats hyper-adapt to N(2)O hypothermia. Increases of intrasessional HP across N(2)O administrations explained both tolerance to N(2)O hypothermia and the unexpected hyperthermia observed in adolescents. These findings raise the possibility that the increased vulnerability to addiction associated with adolescent drug use involves a hyper-adaptive tolerance mechanism.
RATIONALE: Nitrous oxide (N(2)O) can initially lower core temperature (T (core)), but hypothermic tolerance develops with chronic administration. Therefore, one or both of T (core)'s controlling determinants, heat production (HP) and heat loss (HL), must adapt across repeated N(2)O administrations. Simultaneous measurements of HP, HL, and T (core) during chronic N(2)O administrations will elucidate this adaptive process and constitute a rigorous model for studying the systems-level dynamics of tolerance in both mature and young animals. This approach is justified by the need to better understand the increased vulnerability to addiction associated with adolescent drug use. OBJECTIVES: The objective of the study was to measure HL and HP across repeated steady-state administrations of 60% N(2)O in young and mature rats. MATERIALS AND METHODS: Synchronous measurements of HP (indirect calorimetry), HL (direct calorimetry), and T (core) (telemetry) were obtained during 60% N(2)O administrations in adolescent (28-45 days, n = 11) and mature rats (>90 days, n = 8). Rats received five 90-min drug exposures (every other day). RESULTS: Compared to mature rats, adolescents initially exhibited greater hypothermia, but acquired tolerance more rapidly and actually developed hyperthermia during the fifth administration. In both groups, N(2)O consistently increased HL, but progressive increases of intrasessional HP over repeated administrations prevented hypothermia and subsequently promoted hyperthermia in adolescent rats. CONCLUSIONS: Adolescent rats hyper-adapt to N(2)O hypothermia. Increases of intrasessional HP across N(2)O administrations explained both tolerance to N(2)O hypothermia and the unexpected hyperthermia observed in adolescents. These findings raise the possibility that the increased vulnerability to addiction associated with adolescent drug use involves a hyper-adaptive tolerance mechanism.
Authors: K J Kaiyala; B G Leroux; C H Watson; C W Prall; S E Coldwell; S C Woods; D S Ramsay Journal: Pharmacol Biochem Behav Date: 2001-04 Impact factor: 3.533
Authors: Douglas S Ramsay; Salwa Al-Noori; Jason Shao; Brian G Leroux; Stephen C Woods; Karl J Kaiyala Journal: PLoS One Date: 2015-04-16 Impact factor: 3.240